Of gyrators and anyons
- URL: http://arxiv.org/abs/2410.20835v1
- Date: Mon, 28 Oct 2024 08:34:22 GMT
- Title: Of gyrators and anyons
- Authors: O. Kashuba, R. Mummadavarapu, R. -P. Riwar,
- Abstract summary: We show how generic multiterminal circuits can be expressed as gyrator networks with quantized gyration conductance.
Circular scattering in three-terminal quantum dot chains gives rise to a flat topological ground state.
We provide concepts for error correction protocols, and quantum simulations of interacting fermionic (or generally anyonic) many-body systems.
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- Abstract: In recent years there have emerged various ideas to create and control topological excitations in superconducting devices. Notably, nontrivial Chern bands were predicted to exist in conventional multiterminal Josephson junctions, but the Chern number is yet to be experimentally verified, and the pathway towards feasible quantum hardware applications is unclear. Here we show how generic multiterminal circuits can be expressed as gyrator networks with quantized gyration conductance, giving rise to anyonic excitations carrying $q/p$ fractional fluxes ($q,p$ integer), measurable via a fractional Aharonov-Casher phase. The magnitude of interactions between the anyons depends on the flatness of the topological bands, prompting us to investigate circuit-specific band-engineering techniques. Circular scattering in three-terminal quantum dot chains gives rise to a flat topological ground state, where disorder mitigates Chern number fluctuations and the quasiparticle continuum provides a work-around for known limitations to create nontrivial flat bands. Further band-engineering strategies are presented where the superconducting phase is scrambled either via parallelization or dissipative phase transitions. We provide concepts for error correction protocols, and quantum simulations of interacting fermionic (or generally anyonic) many-body systems -- notably, introducing the possibility to mimic fractional quantum Hall physics or to implement local fermionic models that explicitly break the Wigner superselection rule. The latter indicates that a full understanding of multiterminal circuits will require grappling with a virtually unexplored class of parity-breaking quantum field theories.
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